JP2020090261A - vehicle - Google Patents

Abstract

To suppress the influence of a voltage or the like from an external power supply when starting a vehicle and the transmission of noise generated when starting the vehicle to the external power supply.SOLUTION: A vehicle includes a power storage device, a connection part to which an external power source is connectable, a converter connected to the connection part and the power storage device, and a control device that controls the converter. In the vehicle, the control device executes charge control of controlling the converter such that electric power from the external power supply is supplied to the power storage device with voltage conversion, when the external power supply is connected to the connection part, and performs system starting using electric power from the power storage device after shutting off the converter and the external power supply, when charging of the power storage device is terminated.SELECTED DRAWING: Figure 2

Description

The present invention relates to a vehicle.

Conventionally, this type of vehicle has been arranged in an auxiliary battery, an input/output terminal to which a booster cable connected to a rescue vehicle (external power source) can be connected, and an energization path connecting the auxiliary battery and the input/output terminal. The relay, the auxiliary battery controller that controls the relay, and the energizing path that connects the input/output terminal and the auxiliary battery controller so that the direction from the input/output terminal to the auxiliary battery controller is forward. A diode including a diode to be arranged is proposed (for example, see Patent Document 1). In this vehicle, when an external power supply is connected to the input/output terminal, the power from the external power supply is supplied to the auxiliary battery control unit via the diode, and the auxiliary battery control unit is activated. Then, when the user performs a starting operation thereafter, the vehicle is started using the electric power from the external power supply.

JP, 2018-52176, A

In the above-mentioned vehicle, since the vehicle is started by using the electric power from the external power source, when the vehicle is started, the influence of the voltage from the external power source or the noise generated when the vehicle is started is transmitted to the external power source. There is a case to be.

The vehicle of the present invention has a main object to suppress the influence of a voltage from an external power supply when starting the vehicle and the transmission of noise generated when starting the vehicle to the external power supply. ..

The vehicle of the present invention adopts the following means in order to achieve the above-mentioned main object.

The vehicle of the present invention is
A power storage device,
With a connection part that can connect an external power supply,
A converter connected to the connection unit and the power storage device,
A control device for controlling the converter;
A vehicle comprising:
When the external power supply is connected to the connection unit, the control device controls the converter so that power from the external power supply is supplied to the power storage device with voltage conversion, and the power storage device is charged. When the operation is completed, after the converter is disconnected from the external power supply, the system is started using the electric power from the power storage device.
That is the summary.

In the vehicle of the present invention, when the external power supply is connected to the connecting portion, the converter is controlled so that the power from the external power supply is supplied to the power storage device with voltage conversion. Thus, even when the voltage of the power storage device and the external power supply differ to some extent, it is possible to charge the power storage device while suppressing the occurrence of overvoltage or overcurrent in the power storage device. Then, when the charging of the power storage device is completed, the system is started using the electric power from the power storage device after the converter is disconnected from the external power supply. As a result, the system can be booted without being affected by the voltage from the external power supply, and at the same time, noise generated at the system boot can be prevented from being transmitted to the external power supply.

In such a vehicle of the present invention, further comprising a relay for connecting and disconnecting the connecting portion and the converter by turning on and off, the control device, after charging the power storage device, after turning off the relay, The system may be started using electric power from the power storage device. In this case, by turning off the relay, the converter and the external power source connected to the connecting portion can be cut off.

In the vehicle of the aspect of the invention including a relay, the control device may notify that the system can be activated when the converter and the external power supply are shut off. This makes it possible for the user to recognize that the system can be activated (that the system activation instruction may be given).

In the vehicle of the aspect of the invention including a relay, the vehicle further includes a second relay that connects and disconnects the auxiliary machine and the converter and the relay by turning on and off, and the control device is configured such that the external power supply is connected to the connection portion. Then, the second relay may be turned off and the converter may be controlled so that the electric power from the external power supply is supplied to the power storage device with voltage conversion. By doing so, the auxiliary machinery can be more sufficiently protected.

In the vehicle of the present invention, the control device requests the user to disconnect the external power supply from the connection part when charging of the power storage device is completed, and after the external power supply is disconnected from the connection part, The system may be started using electric power from the power storage device. In this case, since the user disconnects the external power supply from the connection section to shut off the converter and the external power supply, the above-mentioned relay need not be provided. As a result, the number of parts can be reduced.

In the vehicle of the present invention, the control device may be operated by receiving power supply from an electric power line that connects the converter, the connecting portion, and a driving portion for traveling.

It is a block diagram which shows the outline of a structure of the motor vehicle 20 as a 1st Example of this invention. It is a flow chart which shows an example of a processing routine. It is explanatory drawing which shows an example of the mode at the time of starting the system of the motor vehicle 20 after the motor vehicle 20 is left for a long period of time. It is a block diagram which shows the outline of a structure of the vehicle 120 of a modification. It is a block diagram which shows the outline of a structure of the vehicle 220 of a modification. It is a block diagram which shows the outline of a structure of the motor vehicle 320 as a 2nd Example of this invention. It is a flow chart which shows an example of a processing routine. It is explanatory drawing which shows an example of the mode at the time of starting the system of the motor vehicle 20 after the motor vehicle 320 is left for a long period of time. It is a block diagram which shows the outline of a structure of the vehicle 420 of a modification. It is a block diagram which shows the outline of a structure of the motor vehicle 520 of a modification. It is a block diagram which shows the outline of a structure of the motor vehicle 620 as a 3rd Example of this invention. It is a flow chart which shows an example of a processing routine. It is explanatory drawing which shows an example of the mode at the time of starting the system of the motor vehicle 620, after the motor vehicle 620 is left for a long period of time. It is a block diagram which shows the outline of a structure of the motor vehicle 720 as a 4th Example. It is a flow chart which shows an example of a processing routine. It is explanatory drawing which shows an example of the mode at the time of starting the system of the motor vehicle 720, after the motor vehicle 720 is left for a long period of time. It is a block diagram which shows the outline of a structure of the motor vehicle 820 of a modification.

Next, modes for carrying out the present invention will be described using examples.

FIG. 1 is a configuration diagram showing an outline of the configuration of an automobile 20 as a first embodiment of the present invention. The vehicle 20 of the first embodiment is configured as an electric vehicle or a hybrid vehicle, and as shown in the drawing, a drive unit 21, an auxiliary battery 40 as a power storage device, an auxiliary DC/DC converter 42, and a diode. 44, a relay 46, an auxiliary device 48, a rescued terminal 50, a relay 52, and an electronic control unit (hereinafter referred to as “ECU”) 60.

The drive unit 21 includes a motor 22, an inverter 23, a high voltage battery 24, a main DC/DC converter 26, and a system main relay 28. The motor 22 is configured as, for example, a synchronous generator motor having a rotor and a stator, and the rotor is connected to a drive shaft (not shown) connected to drive wheels (not shown). The inverter 23 is used to drive the motor 22 and is connected to the positive electrode line L1p and the negative electrode line L1n of the power line L1. The motor 22 is rotationally driven by the switching control of a plurality of switching elements of the inverter 23 by the ECU 60. The high-voltage battery 24 is configured as a lithium-ion secondary battery or a nickel-hydrogen secondary battery having a rated voltage of about several hundreds V, for example.

The main DC/DC converter 26 has one positive electrode terminal and one negative electrode terminal connected to the positive electrode line L1p and the negative electrode line L1n of the power line L1, and the other positive electrode terminal connected to the positive electrode line L2p of the power line L2. The negative electrode terminal on the other side is grounded to the metal body. In the first embodiment, the vehicle body is used as the negative electrode line L2n of the power line L2 and the negative electrode line L3n of the power line L3 described later. Therefore, being “grounded to the vehicle body” is synonymous with “being connected to the negative electrode line L2n of the power line L2” and the “negative electrode line L3n of the power line L3” described later. The main DC/DC converter 26 steps down the power of the power line L1 and supplies it to the power line L2.

The system main relay 28 has a positive electrode relay 29 and a negative electrode relay 30. The positive relay 29 connects and disconnects the positive terminal of the high voltage battery 24 and the positive line L1p of the power line L1 by turning on and off. This positive electrode relay 29 is configured as a normally open type electromagnetic relay, and has a coil 29a and an operating portion 29b. The coil 29a has one end connected to the ECU 60 and the other end grounded to the vehicle body. When the coil 29a is in the energized state, the operating unit 29b is in a connection state that connects the positive terminal of the high voltage battery 24 and the positive line L1p of the power line L1. When the coil 29a is in the non-energized state, the high voltage battery 24 is in the connected state. Is cut off from the positive terminal of the power line L1p of the power line L1.

The negative electrode relay 30 connects and disconnects the negative electrode terminal of the high-voltage battery 24 and the negative electrode line L1n of the power line L1 by turning on and off. The negative electrode relay 30 is configured as a normally open type electromagnetic relay, and has a coil 30a and an operating portion 30b. The coil 30a has one end connected to the ECU 60 and the other end grounded to the vehicle body. When the coil 30a is in the energized state, the operating unit 30b is in a connection state that connects the negative terminal of the high voltage battery 24 and the negative line L1n of the power line L1. When the coil 30a is in the non-energized state, the high voltage battery 24 is in the connected state. The negative electrode terminal and the negative electrode line L1n of the power line L1 are cut off.

The auxiliary battery 40 is configured as, for example, a lithium ion secondary battery having a rated voltage of about 12V to 16V, a nickel hydrogen secondary battery, or a lead storage battery, and its positive electrode terminal is connected to the positive electrode line L3p of the power line L3. Along with this, the negative electrode terminal is grounded to the vehicle body.

The auxiliary DC/DC converter 42 has one positive electrode terminal connected to the positive electrode line L2p of the power line L2, the other positive electrode terminal connected to the positive electrode line L3p of the power line L3, and a negative electrode terminal. It is grounded to the vehicle body. The auxiliary DC/DC converter 42 exchanges electric power between the electric power line L2 and the electric power line L3 with voltage conversion.

The diode 44 is such that the positive electrode line L3p of the power line L3 and the positive electrode line L2p of the power line L2 are in the forward direction from the positive electrode line L3p of the power line L3 to the positive electrode line L2p of the power line L2, and the auxiliary device DC It is connected in parallel to the /DC converter 42.

Relay 46 connects and disconnects the positive terminal of auxiliary battery 40 and the positive line L3p of power line L3 by turning on and off. The relay 46 is configured as a ratchet electromagnetic relay that requires a current for switching between on and off and does not require a current for holding on or off, and has a coil 46a and an operating portion 46b. The coil 46a has one end connected to the ECU 60 and the other end grounded to the vehicle body. When the coil 46a is switched from the non-energized state to the energized state in a shut-off state that shuts off the positive electrode terminal of the auxiliary battery 40 and the positive electrode line L3p of the power line L3, the operating unit 46b and the power line L3p are turned on. A connection state is established in which L3 is connected to the positive electrode line L3p, and the connection state is maintained even when the coil 46a is switched from the energized state to the non-energized state. In addition, when the coil 46a is switched from the non-energized state to the energized state in the connected state, the actuating portion 46b is in the cut-off state, and the cut-off state is maintained even when the coil 46a is changed from the energized state to the non-energized state.

The auxiliary device 48 has a positive electrode terminal connected to the positive electrode line L2p of the power line L2 and a negative electrode terminal grounded to the vehicle body. The auxiliary machine 48 is configured to operate at a voltage similar to the voltage of the auxiliary machine battery 40. Examples of the auxiliary device 48 include an audio system, a power window, and a navigation device.

The rescued terminal 50 has a positive electrode terminal and a negative electrode terminal, and the negative electrode terminal is grounded to the vehicle body. A positive electrode terminal and a negative electrode terminal of an external power supply for rescue (for example, an auxiliary battery of a rescue vehicle) can be connected to the rescued terminal 50 via a cable (booster cable).

The relay 52 connects and disconnects the terminal 50 for rescue and the positive electrode line L2p of the power line L2 by turning on and off. The relay 52 is configured as a ratchet electromagnetic relay and has a coil 52a and an operating portion 52b. The coil 52a has one end connected to the ECU 60 and the other end grounded to the vehicle body. When the coil 52a is switched from the non-energized state to the energized state in a cutoff state that shuts off the positive electrode terminal of the rescued terminal 50 and the positive electrode line L2p of the power line L2, the operating portion 52b is connected to the positive electrode terminal of the rescued terminal 50. The connection state is established in which the power line L2 is connected to the positive electrode line L2p, and the connection state is maintained even when the coil 52a is switched from the energized state to the non-energized state. In addition, when the coil 52a is switched from the non-energized state to the energized state in the connected state, the actuating section 52b is switched to the cutoff state, and is maintained in the cutoff state even when the coil 52a is switched from the energized state to the non-energized state.

Although not shown, the ECU 60 is configured as a microprocessor centered on a CPU, and includes, in addition to the CPU, a ROM that stores a processing program, a RAM that temporarily stores data, an input/output port, and a communication port. .. The ECU 60 has a positive electrode terminal connected to the positive electrode line L2p of the power line L2 and a negative electrode terminal grounded to the vehicle body, and operates by receiving power from the power line L2.

Signals from various sensors are input to the ECU 60 via the input port. The signals input to the ECU 60 include, for example, the rotational position θm from the rotational position sensor that detects the rotational position of the rotor of the motor 22, the phase current Iu from the current sensor that detects the current of each phase of the motor 22, Iv, the voltage Vh from the voltage sensor that detects the voltage of the high voltage battery 24, and the current Ih from the current sensor that detects the current of the high voltage battery 24. In addition, the voltage VL1 from the sensor that detects the voltage of the power line L1, the voltage VL2 from the voltage sensor that detects the voltage of the power line L2, and the voltage VL3 from the voltage sensor that detects the voltage of the power line L3 may be mentioned. it can. Furthermore, the voltage Va from the voltage sensor that detects the voltage of the auxiliary battery 40 and the current Ia from the current sensor that detects the current of the auxiliary battery 40 can also be mentioned. In addition, an on/off signal from the start switch 61 can also be used.

Various control signals are output from the ECU 60 via the output port. Examples of the signal output from the ECU 60 include control signals to the inverter 23, the main DC/DC converter 26, the auxiliary DC/DC converter 42, the auxiliary 48, the display 62, and the like. The ECU 60 controls ON/OFF of the positive electrode relay 29 and the negative electrode relay 30 by turning the coils 29a and 30a into a conducting state or a non-conducting state. Further, by switching the coil 46a from the non-energized state to the energized state, ON/OFF switching of the relay 46 is controlled. Further, by switching the coil 52a from the non-energized state to the energized state, ON/OFF switching of the relay 52 is controlled.

The ECU 60 calculates the storage ratio SOCh of the high-voltage battery 24 based on the current Ih of the high-voltage battery 24 from the current sensor, or calculates the storage ratio SOCh of the auxiliary battery 40 based on the current of the auxiliary battery 40 from the current sensor. It calculates SOCa.

Next, the operation of the automobile 20 of the first embodiment configured in this manner, particularly the operation when the automobile 20 is system-activated after the automobile 20 has been left for a long period of time, will be described. FIG. 2 is a flowchart showing an example of the processing routine. This routine is started when the vehicle 20 is parked and the system is in the stopped state, and is executed by the ECU 60 except for the process of step S140.

In the processing routine of FIG. 2, the ECU 60 first inputs the storage ratio SOCa of the auxiliary battery 40 (step S100), and compares the input storage ratio SOCa of the auxiliary battery 40 with the threshold value SOCa1 (step S110). Here, as for the threshold value SOCa1, the electricity storage ratio SOCa of the auxiliary battery 40 becomes sufficiently small due to the dark current supplied from the auxiliary battery 40 to the ECU 60, the auxiliary device 48 and the like when the automobile 20 is left for a long time. This is a threshold value used to determine whether or not it is 15%, 20%, 25%, or the like. When the electricity storage ratio SOCa of the auxiliary battery 40 is higher than the threshold value SOCa1, the process returns to step S100.

When the electricity storage ratio SOCa of the auxiliary battery 40 reaches the threshold SOCa1 or less in step S110, the ECU 60 turns on the relay 52 (step S120) and then turns off the relay 46 (step S130). Since the relays 46 and 52 are both configured as ratchet electromagnetic relays, the relay 52 is turned on and the relay 46 is turned off by the ECU 60 turning the coils 52a and 46a from the non-energized state to the energized state.

When the relay 46 is turned off in this manner, power is not supplied from the auxiliary battery 40 to the power line L3, the auxiliary DC/DC converter 42, the power line L2, etc., and the ECU 60 stops. Since the relays 46 and 52 are both configured as ratchet electromagnetic relays, even when the ECU 60 is stopped and the coils 46a and 52a of the relays 46 and 52 are in the non-energized state, the relay 52 is held on and the relays are held. 46 is held off. Since the relay 52 is held in the ON state, the rescue target terminal 50 and the power line L2 are connected.

After that, when an external power supply for rescue (for example, an auxiliary machine pressure battery of a rescue vehicle) is connected to the rescued terminal 50 via a cable and a voltage is applied to the rescued terminal 50 (step S140), Electric power is supplied from the rescue terminal 50 to the ECU 60 via the electric power line L2, and the ECU 60 is activated. Then, the ECU 60 turns on the relay 46 (step S150). Here, the relay 46 is turned on by the ECU 60 turning the coil 46a from the non-energized state to the energized state.

Subsequently, the ECU 60 controls the auxiliary DC/DC converter 42 so that the electric power of the electric power line L2 (electric power from the external power supply) is supplied to the electric power line L3 (auxiliary battery 40) with voltage conversion ( Step S160). Thus, even when the voltage of the auxiliary battery 40 and the external power source are different to some extent (for example, about several V), it is possible to suppress the occurrence of overvoltage or overcurrent in the auxiliary battery 40. At this time, the drive unit 21 and the auxiliary device 48 are kept in the stopped state.

Then, the storage ratio SOCa of the auxiliary battery 40 is input (step S170), and the input storage ratio SOCa of the auxiliary battery 40 is compared with the threshold SOCa2 larger than the threshold SOCa1 (step S180). Here, the threshold value SOCa2 is a threshold value used for determining whether or not the amount of power (charge amount) necessary for system startup has been secured, and is, for example, 5%, 10%, 15% or the like that of the threshold value SOCa1. Larger values are used. When the electricity storage ratio SOCa of the auxiliary battery 40 is less than the threshold value SOCa2, the process returns to step S160.

In this way, the processes of steps S160 to S180 are repeatedly executed, and when the electricity storage ratio SOCa of the auxiliary battery 40 reaches the threshold value SOCa2 or more in step S180, the auxiliary DC/DC converter 42 is stopped (step S190), and the relay 52. Is turned off (step S200). Here, the relay 52 is turned off by the ECU 60 turning the coil 52a from the non-energized state to the energized state. When the relay 52 is turned off in this manner, the power line L2 and the rescued terminal 50 to which the external power source is connected are disconnected. Even if the relay 52 is turned off, power is supplied from the auxiliary battery 40 to the ECU 60 via the power line L3, the diode 44, and the power line L2, so that the ECU 60 is maintained in the operating state.

Then, the user is notified that the system can be activated (step S210). This process is performed, for example, by displaying a message such as "system can be activated" on the display 62 or outputting a voice from a speaker (not shown). As a result, the user can be made aware that the system can be started (that the system start instruction may be given).

Then, after waiting for the user's instruction to start the system (step S220), the system is started using the electric power from the auxiliary battery 40 (step S230), and this routine is finished. Here, the system activation instruction is given, for example, when the user turns on the start switch 61. At system startup, for example, the ECU 60 turns on the system main relay 28 (positive electrode relay 29 and negative electrode relay 30). The system main relay 28 is turned on by the ECU 60 energizing the coils 29a and 30a. Since electric power is supplied to the ECU 60 from the auxiliary battery 40 via the electric power line L3, the diode 44, and the electric power line L2, it can be said that the system main relay 28 is turned on by using the electric power from the auxiliary battery 40. .. After the relay 52 is turned off, that is, after the power line L2 and the rescued terminal 50 to which the external power source is connected are shut off, the system is started by using the power from the auxiliary battery 40 to generate the external power source. It is possible to start the system without being affected by the voltage from the system and to prevent noise generated at the time of starting the system from being transmitted to the external power supply.

When the system startup is completed in this way, the ECU 60 controls the main DC/DC converter 26 so that the electric power of the electric power line L1 is supplied to the electric power line L2 with the voltage conversion, and the electric power of the electric power line L2 is accompanied with the voltage conversion. The accessory DC/DC converter 42 is controlled so as to be supplied to the power line L3. As a result, the electric power of the high voltage battery 24 is supplied to the auxiliary battery 40 via the electric power line L1, the main DC/DC converter 26, the electric power line L2, the auxiliary DC/DC converter 42, and the electric power line L3. 40 is charged.

FIG. 3 is an explanatory diagram showing an example of a state in which the system of the automobile 20 is started after the automobile 20 is left for a long period of time. As shown in the figure, the ECU 60 turns on the relay 52 and then turns off the relay 46 when the storage ratio SOCa of the auxiliary battery 40 reaches the threshold value SOCa1 or less (time t11). When the relay 46 is turned off in this way, the ECU 60 stops. After that, when an external power supply for rescue is connected to the terminal 50 for rescue and a voltage is applied to the terminal 50 for rescue (time t12), the ECU 60 is activated. Then, the ECU 60 turns on the relay 46 and controls the accessory DC/DC converter 42 so that the electric power of the electric power line L2 is supplied to the electric power line L3 with voltage conversion. Thereby, the auxiliary battery 40 can be charged using the electric power from the external power supply.

When the storage ratio SOCa of the auxiliary battery 40 reaches the threshold SOCa2 or more (time t13), the auxiliary DC/DC converter 42 is stopped and the relay 52 is turned off to notify that the system can be started. .. Thereafter, when the user issues a system activation instruction (time t14), the system is activated using the electric power from auxiliary battery 40. Then, when the system startup is completed, the main DC/DC converter 26 is controlled so that the power of the power line L1 is supplied to the power line L2 with the voltage conversion, and the power of the power line L2 is converted with the voltage. The accessory DC/DC converter 42 is controlled so as to be supplied to the line L3. Thereby, the auxiliary battery 40 can be charged using the electric power from the high voltage battery 24. After the relay 52 is turned off, the user disconnects the external power supply from the rescued terminal 50.

In the vehicle 20 of the first embodiment described above, while the relay 52 is on, the relay 46 is off, and the ECU 60 is stopped, an external power source for rescue is connected to the rescue terminal 50 and the rescue terminal 50. When a voltage is applied to the ECU 60, the ECU 60 starts. Then, the ECU 60 turns on the relay 46, and the electric power of the electric power line L2 (electric power from the external power source) is supplied to the electric power line L3 (auxiliary battery 40) with voltage conversion, so that the auxiliary equipment DC/DC is supplied. The converter 42 is controlled. This makes it possible to charge the auxiliary battery 40 while suppressing the occurrence of overvoltage or overcurrent in the auxiliary battery 40 even when the voltages of the auxiliary battery 40 and the external power supply differ to some extent. When the charging of the auxiliary battery 40 is completed, the relay 52 is turned off, and then the system is started using the electric power from the auxiliary battery 40 according to the system starting instruction from the user. As a result, the system can be booted without being affected by the voltage from the external power supply, and at the same time, noise generated at the system boot can be prevented from being transmitted to the external power supply.

In the vehicle 20 of the first embodiment, after the auxiliary battery 40 has been charged and the relay 52 has been turned off, the user is informed that the system can be activated, and the user issues a system activation instruction. The system is started by using the electric power from the auxiliary battery 40. However, the system may be automatically started when the relay 52 is turned off after charging the auxiliary battery 40.

Although the vehicle 20 of the first embodiment has the configuration shown in FIG. 1, it may have the configuration of the vehicle 120 of the modified example of FIG. 4 or the configuration of the vehicle 220 of the modified example of FIG. Hereinafter, they will be described in order.

The automobile 120 of FIG. 4 will be described. The vehicle 120 of FIG. 4 has the same hardware configuration as the vehicle 20 of FIG. 1 except that a drive unit 121 is provided instead of the drive unit 21. Therefore, the same hardware configuration of the automobile 120 as that of the automobile 20 is designated by the same reference numeral, and detailed description thereof will be omitted.

The drive unit 121 includes an engine 122, a starter 124, and an alternator 126. The starter 124 is connected to the crankshaft of the engine 122 via, for example, a one-way clutch, has its positive electrode terminal connected to the positive electrode line L2p of the power line L2, and has its negative electrode terminal grounded to the vehicle body. The alternator 126 is connected to the crankshaft of the engine 122 via a belt mechanism 128, has its positive electrode terminal connected to the positive electrode line L2p of the power line L2, and has its negative electrode terminal grounded to the vehicle body.

In this automobile 120, in addition to various signals similar to those of the automobile 20, the crank angle θcr from a crank angle sensor that detects the crank angle of the engine 122 and the like are input to the ECU 60 via an input port. The ECU 60 outputs control signals to the engine 122, the starter 124, and the alternator 126, in addition to various control signals similar to those of the automobile 20, via the output port.

Also in this automobile 120, the ECU 60 executes the processing routine of FIG. Then, in the system startup of step S230 of the processing routine of FIG. 2, the engine 122 and the starter 124 are controlled so that the engine 122 is cranked and started by the starter 124. At this time, power is supplied to the starter 124 from the auxiliary battery 40 via the power line L3, the diode 44, and the power line L2. With such control, the same effect as the automobile 20 can be obtained.

The automobile 220 of FIG. 5 will be described. The automobile 220 of FIG. 5 has the same hardware configuration as the automobile 20 of FIG. 1 except that a drive unit 221 is provided instead of the drive unit 21. Therefore, the same hardware configuration as that of the automobile 20 of the automobile 220 is designated by the same reference numeral, and detailed description thereof will be omitted.

The drive unit 221 includes an engine 222, a motor generator 224, a battery 228, and a DC/DC converter 230. The motor generator 224 is connected to the crankshaft of the engine 222 via a belt mechanism 226, the positive electrode terminal is connected to the positive electrode line L4p of the power line L4, and the negative electrode terminal is grounded to the vehicle body. Note that “grounded to the vehicle body” is synonymous with “negative line L2n of power line L2”, “negative line L3n of power line L3”, and “negative line L4n of power line L4”. Is.

The battery 228 is configured as, for example, a lithium-ion secondary battery or a nickel-hydrogen secondary battery having a rated voltage of about 40V to 50V, the positive electrode terminal is connected to the positive electrode line L4p of the power line L4, and the negative electrode terminal is the vehicle body. Grounded to.

In the DC/DC converter 230, one positive electrode terminal is connected to the positive electrode line L4p of the power line L4, the other positive electrode terminal is connected to the positive electrode line L2p of the power line L2, and the negative electrode terminal is connected to the vehicle body. It is grounded. The DC/DC converter 230 steps down the power of the power line L4 and supplies it to the power line L2, or steps up the power of the power line L2 and supplies it to the power line L4.

In this automobile 220, in addition to various signals similar to those of the automobile 20, the ECU 60 outputs a crank angle θcr from a crank angle sensor that detects the crank angle of the engine 222 and a voltage sensor that detects the voltage of the power line L4. The voltage VL4, the voltage Vh2 from the voltage sensor that detects the voltage of the battery 228, the current Ih2 from the current sensor that detects the current of the battery 228, and the like are input via the input port. In addition to various control signals similar to those of the automobile 20, control signals to the engine 222, the motor generator 224, the DC/DC converter 230, and the like are output from the ECU 60 via the output port. The ECU 60 calculates the storage ratio SOCh2 of the battery 228 based on the current Ih2 of the battery 228 from the current sensor.

In this automobile 220 as well, the ECU 60 executes the processing routine of FIG. Then, in the system startup of step S230 of the processing routine of FIG. 2, the engine 222 and the motor generator 224 are controlled so that the engine 222 is cranked and started by the motor generator 224. At this time, power is supplied to the motor generator 224 from the auxiliary battery 40 via the power line L3, the diode 44, and the power line L2. With such control, the same effect as the automobile 20 can be obtained.

FIG. 6 is a configuration diagram showing an outline of the configuration of an automobile 320 as a second embodiment of the present invention. The automobile 320 of FIG. 6 is different from the automobile of the first embodiment shown in FIG. 1 except that the relay 322 and the diodes 330 and 332 are provided, and the connection destination of the coil 46a of the relay 46 and the connection destination of the ECU 60 are different. It has the same hardware configuration as 20. Therefore, the same hardware configuration as that of the automobile 20 of the automobile 320 is designated by the same reference numeral, and detailed description thereof will be omitted.

The relay 322 is provided between the main DC/DC converter 26 and the auxiliary machine 48 side and the auxiliary machine DC/DC converter 42, the diode 44, and the relay 52 (terminal 50 for rescue) in the positive line L2p of the power line L2. By turning on and off, the main DC/DC converter 26 and the auxiliary machine 48 side and the auxiliary machine DC/DC converter 42, the diode 44, and the relay 52 side are connected and disconnected. The relay 322 is configured as a ratchet electromagnetic relay and has a coil 322a and an operating portion 322b. The coil 322a has one end connected to the ECU 60 and the other end grounded to the vehicle body. When the coil 322a is switched from the non-energized state to the energized state, the operating portion 322b is in a shut-off state that shuts off the main DC/DC converter 26 or the accessory 48 side from the accessory DC/DC converter 42, the diode 44, or the relay 52 side. , The main DC/DC converter 26 or the auxiliary machine 48 side is connected to the auxiliary machine DC/DC converter 42, the diode 44, or the relay 52 side, and even if the coil 322a is switched from the energized state to the non-energized state. Hold the connection status. In addition, the operating portion 322b is in the disconnected state when the coil 46a is switched from the non-energized state to the energized state in the connected state, and maintains the disconnected state even when the coil 322a is switched from the energized state to the non-energized state.

One end of the coil 46a of the relay 46 is connected to the ECU 60 via the diode 330 and is connected to the rescued terminal 50 via the diode 332, and the other end of the coil 46a is grounded to the vehicle body. .. The diode 330 is arranged so that the direction from the ECU 60 to the coil 46a is the forward direction, and the diode 332 is arranged so that the direction from the rescued terminal 50 to the coil 46a is the forward direction. Therefore, the higher voltage of the voltage of the ECU 60 and the voltage of the rescued terminal 50 is applied to the coil 46a.

The positive terminal of the ECU 60 is connected to the positive line of the power line L3, and the negative terminal is grounded to the vehicle body. The ECU 60 controls switching of the relay 322 between ON and OFF by turning the coil 322a from the non-energized state to the energized state.

Next, an operation of the thus configured automobile 320 of the second embodiment, particularly an operation when the automobile 320 is system-activated after the automobile 320 is left for a long period of time, will be described. FIG. 7 is a flowchart showing an example of the processing routine. This routine is started when the automobile 320 is parked and the system is in a stopped state, and is executed by the ECU 60 except for the processes of steps S140 and S150b. Further, this routine is the same as the processing routine of FIG. 2 except that the processing of steps S115 and S205 is added, and that the processing of step S150b that is not processing by the ECU 60 is replaced with the processing of step S150 by the ECU 60. is there. Therefore, the same steps as those of the processing routine of FIG. 2 among the processing routine of FIG. 7 are designated by the same step numbers, and detailed description thereof will be omitted.

In the processing routine of FIG. 7, when the storage ratio SOCa of the auxiliary battery 40 reaches the threshold SOCa1 or less (step S110), the ECU 60 turns off the relay 322 (step S115) and then turns on the relay 52 (step S115). In step S120), the relay 46 is turned off (step S130). Since the relay 322 is configured as a ratchet electromagnetic relay, the relay 322 is turned off by the ECU 60 turning the coil 322a from the non-energized state to the energized state. As described above, when the relay 46 is turned off, the ECU 60 stops. Even if the ECU 60 is stopped and the coil 322a of the relay 322 is de-energized, the relay 322 is held off.

After that, when an external power supply for rescue is connected to the terminal for rescue 50 and a voltage is applied to the terminal for rescue 50 (step S140), the coil 46a of the relay 46 is transmitted from the terminal for rescue 50 via the diode 332. Is supplied to the coil 46a to turn it on, and the relay 46 is turned on (step S150b). When the relay 46 is turned on, power is supplied from the auxiliary battery 40 to the ECU 60 via the power line L3, and the ECU 60 is activated.

Subsequently, the ECU 60 causes the electric power of the electric power line L2 (electric power from the external power source) to be converted to the electric power line L3 (auxiliary battery 40) along with the voltage conversion until the electricity storage ratio SOCa of the auxiliary battery 40 reaches the threshold value SOCa2 or more. The accessory DC/DC converter 42 is controlled so as to be supplied (steps S160 to S180). Thereby, even when the voltage of the auxiliary battery 40 and the external power supply are different to some extent, it is possible to suppress the occurrence of overvoltage or overcurrent in the auxiliary battery 40. Further, at this time, since the relay 322 is off, even when an external power source having a relatively high voltage (for example, a voltage similar to the rated voltage of the battery 228) is connected to the rescued terminal 50, the auxiliary device 48 A relatively high voltage can be prevented from being applied to the auxiliary device 48, and the auxiliary device 48 can be protected more sufficiently. At this time, the drive unit 21 and the auxiliary device 48 are kept in the stopped state.

When the storage ratio SOCa of the auxiliary battery 40 reaches the threshold SOCa2 or more (step S180), the auxiliary DC/DC converter 42 is stopped (step S190) and the relay 52 is turned off (step S200). The relay 322 is turned on (step S205). Here, the relay 322 is turned on by the ECU 60 turning the coil 322a from the non-energized state to the energized state.

Then, the user is informed that the system can be activated (step S210), waits for the system activation instruction by the user (step S220), and the system is activated using the electric power from the auxiliary battery 40. (Step S230), this routine is ended. After the relay 52 is turned off, that is, after the power line L2 and the rescued terminal 50 to which the external power source is connected are shut off, the system is started by using the power from the auxiliary battery 40 to generate the external power source. It is possible to start the system without being affected by the voltage from the system and to prevent noise generated at the time of starting the system from being transmitted to the external power supply.

FIG. 8 is an explanatory diagram showing an example of a state in which the system of the vehicle 20 is started after the vehicle 320 is left for a long period of time. As shown in the figure, the ECU 60 turns off the relay 322, turns on the relay 52, and then turns off the relay 46 when the electricity storage ratio SOCa of the auxiliary battery 40 reaches the threshold SOCa1 or less (time t21). When the relay 46 is turned off in this way, the ECU 60 stops. After that, when an external power supply for rescue is connected to the terminal for rescue 50 and a voltage is applied to the terminal for rescue 50 (time t22), the relay 46 is turned on, which causes the ECU 60 to start. Then, the ECU 60 controls the accessory DC/DC converter 42 so that the electric power of the electric power line L2 is supplied to the electric power line L3 with voltage conversion. Thereby, the auxiliary battery 40 can be charged using the electric power from the external power supply.

When the storage ratio SOCa of the auxiliary battery 40 reaches the threshold SOCa2 or more (time t23), the auxiliary DC/DC converter 42 is stopped, the relay 52 is turned off and the relay 322 is turned on, and the system is started. Notify that it is possible. After that, when the user issues a system activation instruction (time t24), the system is activated using the electric power from auxiliary battery 40. Then, when the system startup is completed, the main DC/DC converter 26 is controlled so that the power of the power line L1 is supplied to the power line L2 with the voltage conversion, and the power of the power line L2 is converted with the voltage. The accessory DC/DC converter 42 is controlled so as to be supplied to the line L3. Thereby, the auxiliary battery 40 can be charged using the electric power from the high voltage battery 24. After the relay 52 is turned off, the user disconnects the external power supply from the rescued terminal 50.

In the automobile 320 of the second embodiment described above, the external power source for rescue is connected to the terminal 50 for rescue while the relay 322 is off, the relay 52 is on, the relay 46 is off, and the ECU 60 is stopped. When a voltage is applied to the rescued terminal 50, the relay 46 is turned on, which activates the ECU 60. Then, ECU 60 controls auxiliary machine DC/DC converter 42 such that the electric power of electric power line L2 (electric power from the external power supply) is supplied to electric power line L3 (auxiliary battery 40) with voltage conversion. This makes it possible to charge the auxiliary battery 40 while suppressing the occurrence of overvoltage or overcurrent in the auxiliary battery 40 even when the voltages of the auxiliary battery 40 and the external power supply differ to some extent. Further, at this time, since the relay 322 is off, it is possible to avoid applying a relatively high voltage to the auxiliary machine 48 even when an external power source having a relatively high voltage is connected to the rescued terminal 50. The auxiliary machine 48 can be protected more sufficiently. When the charging of the auxiliary battery 40 is completed, the relay 52 is turned off and the relay 322 is turned on, and then the system is started using the electric power from the auxiliary battery 40 according to the system start instruction from the user. As a result, the system can be booted without being affected by the voltage from the external power supply, and at the same time, noise generated at the system boot can be prevented from being transmitted to the external power supply.

In the automobile 320 of the second embodiment, after the auxiliary battery 40 is charged and the relay 52 is turned off and the relay 322 is turned on, the user is informed that the system can be activated, and the system is set by the user. When the activation instruction is given, the system is activated by using the electric power from the auxiliary battery 40. However, the system may be automatically started when the auxiliary battery 40 is charged and the relay 52 is turned off and the relay 322 is turned on.

Although the vehicle 320 of the second embodiment has the configuration shown in FIG. 6, it may have the configuration of the vehicle 420 of the modification of FIG. 9 or the configuration of the vehicle 520 of the modification of FIG. Hereinafter, they will be described in order.

The automobile 420 of FIG. 9 will be described. The automobile 420 of FIG. 9 has the same hardware configuration as the automobile 320 of FIG. 6, except that the drive unit 21 is replaced by a drive unit 121 similar to that of the automobile 120 of FIG. 4. In this automobile 420, the relay 322 includes the starter 124, the alternator 126, the auxiliary machine 48 side, the auxiliary machine DC/DC converter 42, the diode 44, and the relay 52 (terminal 50 for rescue) on the positive electrode line L2p of the power line L2. Is connected between the starter 124, the alternator 126, the auxiliary machine 48 side and the auxiliary machine DC/DC converter 42, the diode 44, and the relay 52 side by turning on and off. In this automobile 420 as well, the ECU 60 executes the processing routine of FIG. 7. As a result, the same effect as the automobile 320 can be obtained.

The automobile 520 in FIG. 10 will be described. The automobile 520 of FIG. 10 has the same hardware configuration as the automobile 320 of FIG. 6, except that the automobile 520 of FIG. 10 includes a drive unit 221 similar to the automobile 220 of FIG. In this automobile 520, the relay 322 is connected to the auxiliary machine 48 side in the positive electrode line L2p of the power line L2, the DC/DC converter 230, the auxiliary machine DC/DC converter 42, the diode 44, and the relay 52 (terminal 50 for rescue). Is connected between the auxiliary machine 48 side and the DC/DC converter 230, the auxiliary machine DC/DC converter 42, the diode 44, or the relay 52 side by turning on/off. In this automobile 520 as well, the ECU 60 executes the processing routine of FIG. 7. As a result, the same effect as the automobile 320 can be obtained.

FIG. 11 is a configuration diagram showing an outline of the configuration of an automobile 620 as a third embodiment of the present invention. The automobile 620 of FIG. 11 is provided with a capacitor 622, a diode 44 is not provided, a connection destination of the positive terminal of the auxiliary device 48 or a connection destination of the positive terminal of the ECU 60 is different, and a position of the relay 52 is different. Except for this, the vehicle has the same hardware configuration as the automobile 120 of the modification of the first embodiment shown in FIG. Therefore, of the automobile 620, the same hardware configuration as that of the automobile 120 is designated by the same reference numeral, and detailed description thereof will be omitted.

The capacitor 622 is configured as a capacitor having a rated voltage of, for example, about 12V to 16V (about the same as the auxiliary battery 40), one terminal of which is connected to the positive electrode line L2p of the power line L2 and the other terminal of which is connected. It is grounded to the vehicle body. The auxiliary device 48 has a positive electrode terminal connected to the positive electrode line L3p of the power line L3 and a negative electrode terminal grounded to the vehicle body. The relay 52 connects and disconnects the terminal 50 for rescue and the positive electrode line L3p of the power line L3 by turning on and off.

The ECU 60 has a positive electrode terminal connected to the positive electrode line L3p of the power line L3 and a negative electrode terminal grounded to the vehicle body, and operates by receiving power from the power line L3. In addition to various signals similar to those of the automobile 120, the ECU 60 receives the voltage Vc from the voltage sensor that detects the voltage of the capacitor 622 and the current Ic from the current sensor that detects the current of the capacitor 622 via the input port. Is entered. The ECU 60 calculates the storage ratio SOCc of the capacitor 622 based on the current Ic of the capacitor 622 from the current sensor.

Next, the operation of the thus constructed automobile 620 of the third embodiment, particularly the operation when the automobile 620 is started up after being left for a long period of time, will be described. FIG. 12 is a flowchart showing an example of the processing routine. This routine is started when the vehicle 620 is parked and the system is in a stopped state, and is executed by the ECU 60 except for the process of step S140. In addition, this routine is different from that shown in FIG. 2 except that it has steps S160c to S180c and 230c in place of the steps S160 to S180 and S230, and that it has step S150 after the step S230c. It is the same as the processing routine. Therefore, of the processing routines of FIG. 12, the same processings as those of the processing routine of FIG. 2 are designated by the same step numbers, and detailed description thereof will be omitted.

In the processing routine of FIG. 12, when the power storage ratio SOCa of the auxiliary battery 40 reaches the threshold SOCa1 or less (step S110), the ECU 60 turns on the relay 52 (step S120) and then turns off the relay 46 (step S120). S130). As described above, when the relay 46 is turned off, the ECU 60 stops. After that, when an external power supply for rescue is connected to the terminal 50 for rescue and a voltage is applied to the terminal 50 for rescue (step S140), power is supplied from the terminal 50 for rescue to the ECU 60 via the power line L3. , The ECU 60 is activated.

Then, the ECU 60 controls the accessory DC/DC converter 42 so that the electric power of the electric power line L3 (electric power from the external power supply) is supplied to the electric power line L2 (capacitor 622) with voltage conversion (step S160c). .. Thereby, even when the voltage of the capacitor 622 and the voltage of the external power source are different to some extent, it is possible to suppress the occurrence of overvoltage or overcurrent in the capacitor 622. At this time, the drive unit 121 and the auxiliary device 48 are kept in the stopped state.

Subsequently, the storage ratio SOCc of the capacitor 622 is input (step S170c), and the input storage ratio SOCc of the capacitor 622 is compared with the threshold SOCc1 (step S180c). Here, the threshold SOCc1 is a threshold used to determine whether or not the amount of power (charge amount) necessary for system activation has been secured, and for example, 25%, 30%, 35% or the like is used. When the storage ratio SOCc of the capacitor 622 is less than the threshold SOCc1, the process returns to step S160c.

In this way, the processes of steps S160c to S180c are repeatedly executed, and when the storage ratio SOCc of the capacitor 622 reaches the threshold SOCc1 or more in step S180c, the auxiliary DC/DC converter 42 is stopped (step S190) and the relay 52 is turned off. (Step S200). Then, it notifies the user that the system can be activated (step S210), waits for the user's instruction to activate the system (step S220), and then activates the system using the power from the capacitor 622 (step). S230c). When the engine 122 is started at system startup, the starter 124 is supplied with power from the capacitor 622 via the power line L2. After the relay 52 is turned off, that is, after the power line L3 and the rescued terminal 50 to which the external power source is connected are shut off, the system is started using the power from the capacitor 622, so that the power from the external power source is supplied. The system can be started up without being affected by the voltage and the like, and noise generated at the time of starting up the system can be prevented from being transmitted to the external power supply.

When the system is activated, the relay 46 is turned on (step S150), and this routine ends. When the relay 46 is turned on, the ECU 60 controls the accessory DC/DC converter 42 so that the electric power of the electric power line L2 is supplied to the electric power line L3 with voltage conversion. As a result, the electric power from the capacitor 622 or the electric power generated by the alternator 126 using the power from the engine 122 is supplied to the auxiliary battery 40 via the electric power line L2, the auxiliary DC/DC converter 42, and the electric power line L3. Then, the auxiliary battery 40 is charged.

FIG. 13 is an explanatory diagram showing an example of a state in which the system of the automobile 620 is started after the automobile 620 is left for a long period of time. As shown in the figure, the ECU 60 turns on the relay 52 and then turns off the relay 46 when the storage ratio SOCa of the auxiliary battery 40 reaches the threshold value SOCa1 or less (time t31). When the relay 46 is turned off in this way, the ECU 60 stops. After that, when an external power supply for rescue is connected to the terminal 50 for rescue and a voltage is applied to the terminal 50 for rescue (time t32), the ECU 60 is activated. Then, the ECU 60 controls the accessory DC/DC converter 42 so that the electric power of the electric power line L3 is supplied to the electric power line L2 with voltage conversion. Thereby, the capacitor 622 can be charged using the electric power from the external power supply.

Then, when the storage ratio SOCc of the capacitor 622 reaches the threshold SOCc1 or more (time t33), the auxiliary DC/DC converter 42 is stopped and the relay 52 is turned off to notify that the system can be started. Thereafter, when the user issues a system activation instruction (time t34), the system is activated using the power from capacitor 622. Then, when the system startup is completed, the relay 46 is turned on, and the accessory DC/DC converter 42 is controlled so that the power of the power line L2 is supplied to the power line L3 with voltage conversion. As a result, the auxiliary battery 40 can be charged using the electric power from the capacitor 622 or the electric power generated by the alternator 126. After the relay 52 is turned off, the user disconnects the external power supply from the rescued terminal 50.

In the vehicle 620 of the third embodiment described above, the external power source for rescue is connected to the rescue terminal 50 while the relay 52 is on, the relay 46 is off, and the ECU 60 is stopped, and the rescue terminal 50 is connected. When a voltage is applied to the ECU 60, the ECU 60 starts. Then, ECU 60 controls auxiliary machine DC/DC converter 42 such that the electric power of electric power line L3 (electric power from the external power supply) is supplied to electric power line L2 (capacitor 622) with voltage conversion. Thereby, even when the voltage of the capacitor 622 and the voltage of the external power source differ to some extent, the capacitor 622 can be charged while suppressing the occurrence of overvoltage or overcurrent in the capacitor 622. When the charging of the auxiliary battery 40 is completed, the relay 52 is turned off, and then the system is started using the power from the capacitor 622 according to the system start instruction from the user. As a result, the system can be booted without being affected by the voltage from the external power supply, and at the same time, noise generated at the system boot can be prevented from being transmitted to the external power supply.

In the automobile 620 of the third embodiment, after the auxiliary battery 40 is charged and the relay 52 is turned off, the user is informed that the system can be activated, and when the user issues a system activation instruction, The system is started by using the electric power from the auxiliary battery 40. However, the system may be automatically started when the relay 52 is turned off after charging the auxiliary battery 40.

FIG. 14 is a configuration diagram showing an outline of the configuration of an automobile 720 as the fourth embodiment. The vehicle 720 of FIG. 14 has the same hardware configuration as the vehicle 20 of the first embodiment shown in FIG. 1 except that the vehicle 52 is not provided with the relay 52. Therefore, of the automobile 720, the same hardware configuration as that of the automobile 20 is designated by the same reference numeral, and detailed description thereof will be omitted.

Next, the operation of the automobile 720 of the fourth embodiment configured as described above, particularly the operation when the automobile 720 system is started after the automobile 720 is left for a long period of time, will be described. FIG. 15 is a flowchart showing an example of the processing routine. This routine is started when the vehicle 720 is parked and the system is in a stopped state, and is executed by the ECU 60 except for the process of step S140. Further, this routine is the same as the processing routine of FIG. 2 except that it does not include the processing of steps S140 and S200 and that the processing of steps S192 and S194 is added. Therefore, of the processing routines of FIG. 12, the same processings as those of the processing routine of FIG. 2 are designated by the same step numbers, and detailed description thereof will be omitted.

In the processing routine of FIG. 15, the ECU 60 turns off the relay 46 (step S130) when the storage ratio SOCa of the auxiliary battery 40 reaches the threshold value SOCa1 or less (step S110). As described above, when the relay 46 is turned off, the ECU 60 stops. After that, when an external power supply for rescue is connected to the terminal 50 for rescue and a voltage is applied to the terminal 50 for rescue (step S140), the ECU 60 is activated. Then, the ECU 60 turns on the relay 46 (step S150), and the electric power of the electric power line L2 (electric power from the external power supply) is converted into electric power until the power storage ratio SOCa of the auxiliary battery 40 reaches the threshold SOCa2 or more. The auxiliary DC/DC converter 42 is controlled so as to be supplied to the line L3 (auxiliary battery 40) (steps S160 to S180). Thereby, even when the voltage of the auxiliary battery 40 and the external power supply are different to some extent, it is possible to suppress the occurrence of overvoltage or overcurrent in the auxiliary battery 40. At this time, the drive unit 21 and the auxiliary device 48 are kept in the stopped state. When the storage ratio SOCa of the auxiliary battery 40 reaches the threshold SOCa2 or more (step S180), the auxiliary DC/DC converter 42 is stopped to be driven (step S190).

Subsequently, the user is requested to disconnect the external power source from the rescued terminal 50 (step S192), and waits for the external power source to be disconnected from the rescued terminal 50 (step S194). The process of step S192 is performed, for example, by displaying a message such as "Please remove the cable from the terminal for rescue" on the display 62 or outputting a voice from a speaker (not shown). This allows the user to recognize that it is necessary to disconnect the external power supply from the rescued terminal 50. The process of step S194 can be performed, for example, by checking the voltage of the power line L2. This is based on the fact that when the external power supply is disconnected from the rescued terminal 50, the voltage of the power line L2 drops from the voltage of the external power supply to a voltage approximately equal to the open circuit voltage of the auxiliary battery 40.

Then, when the external power source is disconnected from the rescued terminal 50, the user is informed that the system can be activated (step S210), and waits for the system activation instruction by the user (step S220). The system is started using the electric power from the auxiliary battery 40 (step S230), and this routine is finished. After the external power supply is removed from the rescued terminal 50, the system startup can be performed by using the power from the auxiliary battery 40, so that the system startup can be performed without being affected by the voltage or the like from the external power supply. At the same time, it is possible to prevent noise generated at system startup from being transmitted to the external power supply.

FIG. 16 is an explanatory diagram showing an example of how the system of the automobile 720 is started after the automobile 720 is left for a long period of time. As shown in the figure, the ECU 60 turns off the relay 46 when the storage rate SOCa of the auxiliary battery 40 reaches the threshold value SOCa1 or less (time t41). When the relay 46 is turned off in this way, the ECU 60 stops. After that, when an external power supply for rescue is connected to the terminal 50 for rescue and a voltage is applied to the terminal 50 for rescue (time t42), the ECU 60 is activated. Then, the ECU 60 turns on the relay 46 and controls the accessory DC/DC converter 42 so that the electric power of the electric power line L2 is supplied to the electric power line L3 with voltage conversion. Thereby, the auxiliary battery 40 can be charged using the electric power from the external power supply.

Then, when the storage ratio SOCa of the auxiliary battery 40 reaches the threshold value SOCa2 or more (time t43), the auxiliary DC/DC converter 42 is stopped, and the user is requested to disconnect the external power source from the rescued terminal 50. .. When the user disconnects the external power supply from the rescued terminal 50 (time t44), the user is notified that the system can be activated. Thereafter, when the user issues a system activation instruction (time t45), the system is activated using the electric power from auxiliary battery 40. Then, when the system startup is completed, the main DC/DC converter 26 is controlled so that the power of the power line L1 is supplied to the power line L2 with the voltage conversion, and the power of the power line L2 is converted with the voltage. The accessory DC/DC converter 42 is controlled so as to be supplied to the line L3. Thereby, the auxiliary battery 40 can be charged using the electric power from the high voltage battery 24.

In the vehicle 720 of the fourth embodiment described above, the external power source for rescue is connected to the terminal 50 for rescue and the voltage is applied to the terminal 50 for rescue while the relay 46 is off and the ECU 60 is stopped. Then, the ECU 60 is activated. Then, the ECU 60 turns on the relay 46, and the electric power of the electric power line L2 (electric power from the external power source) is supplied to the electric power line L3 (auxiliary battery 40) with voltage conversion, so that the auxiliary equipment DC/DC is supplied. The converter 42 is controlled. This makes it possible to charge the auxiliary battery 40 while suppressing the occurrence of overvoltage or overcurrent in the auxiliary battery 40 even when the voltages of the auxiliary battery 40 and the external power supply differ to some extent. Then, when charging of the auxiliary battery 40 is completed, the user is requested to disconnect the external power source from the rescued terminal 50, and when the user disconnects the external power source from the rescued terminal 50, the user starts the system activation instruction. Accordingly, the system is started using the electric power from the auxiliary battery 40. As a result, the system can be booted without being affected by the voltage from the external power supply, and at the same time, noise generated at the system boot can be prevented from being transmitted to the external power supply. Further, since the user removes the external power supply from the terminal 50 for rescue, the relay 52 need not be provided unlike the automobiles 20, 120, 220, 320, 420, 520, 620 of the first to third embodiments. As a result, the number of parts can be reduced.

In the automobile 720 of the fourth embodiment, when the external battery is disconnected from the rescued terminal 50 by the user after the charging of the auxiliary battery 40 is completed, the user is informed that the system can be activated. However, the fact may not be notified to the user.

In the automobile 720 of the fourth example, when the external battery is disconnected from the terminal 50 for rescue after the charging of the auxiliary battery 40 is finished, the user is notified that the system can be started, When the user gives an instruction to start the system, the electric power from the auxiliary battery 40 is used to start the system. However, the system may be automatically started when the external power source is removed from the rescued terminal 50 by the user.

Although the vehicle 720 of the fourth embodiment has the configuration shown in FIG. 14, it may have the configuration of the vehicle 820 of the modification of FIG. The automobile 820 of FIG. 17 has the same hardware configuration as the automobile 120 of the modified example of the first embodiment shown in FIG. 4 except that the automobile 52 is not provided. Also in this automobile 820, the ECU 60 executes the processing routine of FIG. As a result, the same effect as the automobile 720 can be obtained.

In the automobiles 20, 120, 220, 320, 420, 520, 620, 720, 820 of the first to fourth embodiments and their modifications, the relay 46 is configured as a ratchet electromagnetic relay, but it is normal. It may be configured as an open type electromagnetic relay. Further, in the automobiles 320, 420, and 520 of the second embodiment and its modifications, the relay 322 is configured as a ratchet electromagnetic relay, but it may be configured as a normally open type electromagnetic relay.

The automobiles 20, 120, 220, 620, 720, and 820 of the first, third, and fourth embodiments and the modifications are provided with the relay 46, but may not be provided with the relay 46. On the other hand, in the automobiles 320, 420, and 520 of the second embodiment and the modified examples, the external power source for rescue is connected to the rescue terminal 50 while the relay 46 is off and the ECU 60 is stopped, and the rescue operation is performed. When a voltage is applied to the terminal for use 50, the relay 46 is turned on, and the ECU 60 is activated by supplying power from the auxiliary battery 40 to the ECU 60 via the power line L3. Therefore, before the auxiliary battery 40 cannot be discharged. It is necessary to keep the relay 46 off.

Correspondence between the main elements of the embodiment and the main elements of the invention described in the column of means for solving the problem will be described. In the first, second, and fourth embodiments, the auxiliary battery 40 corresponds to a "power storage device", the auxiliary DC/DC converter 42 corresponds to a "converter", and the ECU 60 corresponds to a "control device". In the third embodiment, the capacitor 622 corresponds to the “power storage device”, the auxiliary DC/DC converter 42 corresponds to the “converter”, and the ECU 60 corresponds to the “control device”.

The correspondence between the main elements of the embodiment and the main elements of the invention described in the column of means for solving the problem is the same as that of the embodiment described in the section of means for solving the problem. This is an example for specifically explaining the mode for carrying out the invention, and does not limit the elements of the invention described in the column of means for solving the problem. That is, the interpretation of the invention described in the column of means for solving the problem should be made based on the description in that column, and the embodiment is the invention of the invention described in the column of means for solving the problem. This is just a specific example.

Although the embodiments for carrying out the present invention have been described above with reference to the embodiments, the present invention is not limited to these embodiments, and various embodiments are possible within the scope not departing from the gist of the present invention. Of course, it can be implemented.

INDUSTRIAL APPLICABILITY The present invention can be used in the vehicle manufacturing industry and the like.

20, 120, 220, 320, 420, 520, 620, 720, 820 Automobile, 21, 121, 221 Drive unit, 22 Motor, 23 Inverter, 24 High voltage battery, 26 Main DC/DC converter, 28 System main relay, 29 positive electrode relay, 29a, 30a, 46a, 52a, 322a coil, 29b, 30b, 46b, 52b, 322b operating part, 30 negative electrode relay, 40 auxiliary battery, 42 auxiliary DC/DC converter, 44 diode, 46, 52 , 322 relay, 48 auxiliary equipment, 50 terminal for rescue, 60 electronic control unit (ECU), 61 start switch, 62 display, 122, 222 engine, 124 starter, 126 alternator, 128,226 belt mechanism, 224 motor generator, 228 battery, 230 DC/DC converter, 330, 332 diode, 622 capacitor, L1, L2, L3, L4 power line, L1n, L2n, L3n, L4n negative electrode line, L1p, L2p, L3p, L4p positive electrode line.

Claims (5)

A power storage device,
With a connection part that can connect an external power supply,
A converter connected to the connection unit and the power storage device,
A control device for controlling the converter;
A vehicle comprising:
When the external power supply is connected to the connection unit, the control device controls the converter so that power from the external power supply is supplied to the power storage device with voltage conversion, and the power storage device is charged. When the operation is completed, after the converter is disconnected from the external power supply, the system is started using the electric power from the power storage device.
vehicle. The vehicle according to claim 1,
Further comprising a relay for connecting and disconnecting the connecting portion and the converter by turning on and off,
When the control device finishes charging the power storage device, after turning off the relay, the control device performs system startup using electric power from the power storage device,
vehicle. The vehicle according to claim 2,
The control device notifies that the system can be started when the converter and the external power supply are shut off.
vehicle. The vehicle according to claim 2 or 3, wherein
A second relay for connecting and disconnecting the auxiliary machine and the converter and the relay by turning on and off,
When the external power supply is connected to the connection unit, the control device turns off the second relay so that the power from the external power supply is supplied to the power storage device with voltage conversion. To control the
vehicle. The vehicle according to claim 1,
When the control device finishes charging the power storage device, requests the user to disconnect the external power supply from the connection unit, and removes the power from the power storage device after the external power supply is disconnected from the connection unit. System boot using
vehicle.

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